SU1400834A1 - Apparatus for checking eccentricity of coating of welding electrodes - Google Patents

Abstract

The invention relates to welding production, in particular, to means of non-destructive testing of the eccentricity of coating electrodes for electric arc welding, and can be used in electrode production in various fields of engineering. The goal is to improve the accuracy and performance of control electrodes. With the rotation of the electrode with eccentric. By the triple positioning of the coating with respect to its rod, the equilibrium of the bridge, in which the inductive sensors of the measuring unit are included, is disturbed. The inductance change signal is amplified and fed to the inputs of the peak detector and the maximum signal value detection unit. The output of the detector is the maximum value of the signal during the measurement time, which is specified by means of forma- tion of pulses. At the output of the block for determining the maximum signal value, a signal appears only when the maximum value of the measured signal at the amplifier output is reached. The indication time is determined by the pulse duration of another shaper. The device allows you to select the maximum signal corresponding to the eccentricity value, regardless of the speed of rotation of the electrode. 1 sludge. i (/) s - g

Description

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The invention relates to welding production, in particular to means for non-destructive testing of the eccentricity of the coating of electrodes for arc welding, and can be used in electrode production in various fields of engineering.

The aim of the invention is to improve the accuracy and performance of the control.

The drawing shows a block diagram of the device.

The device contains a subdivisionally connected measurement unit 1, made, for example, in the form of two identical inductive transducers included in a bridge measuring circuit, and a ring diode detector, amplifier 2, peak detector 3, display unit 4 and serially connected unit 5 for determining the maximum value signal, the first 6 and second 7 pulse shapers. The input unit 5 for determining the maximum value of the signal is connected to the output of the force of bodies 2, the output of the generator 6 is connected to the control input of the display unit 4, and the output of the generator 7 is connected to the control input of the peak detector 3. I

The display unit 4 can be performed, for example, in the form of an analog-to-digital converter and a digital indicator. At the output of block 5 for determining the maximum signal value, a signal appears only when the envelope of the signal at the output of amplifier 2 reaches its highest value. Therefore, block 5 for determining the maximum value of a signal can be made in the form of serially connected standard blocks, for example, a differentiating amplifier and voltage comparator. The pulse shaper 6, when a signal from the output of block 5 arrives, generates a square pulse determining the indication time of block 4 and the measurement time of the peak detector 3. The pulse shaper 7 is triggered on the falling edge of the pulse of the shaper 6 and produces a short reset pulse for the peak detector 3. Inductive converters Measurement unit 1 for control is diametrically opposed.

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relative to the electrode and in contact with the surface of the coating.

The device works as follows.

The electrode being tested is placed on supports (not shown) and a rotary motion is attached to it. The bridge measuring circuit of the measurement unit 1 is connected to an alternating voltage source (not shown).

If the electrode coating is located concentrically with respect to the rod, then when it rotates, the distance to any of the inductive converters of the measurement unit 1 remains constant. The inductive resistance of the transducers also does not change. The equilibrium of the bridge circuit is not disturbed, the signal at the output of block 1 is zero. The display unit 4 does not work.

If the electrode coating is located eccentrically with respect to the rod, then the distance between the rods and the inductive converters of the measuring unit 1 changes as the electrode rotates, and the change in the distance to each of the converters is equal in magnitude but opposite in sign.

A change in distance leads to a change in the inductive resistance of the transducers, which causes an imbalance in the bridge. A periodically varying signal appears at the output of measuring unit 1. The signal amplitude depends on the magnitude of eccentricity. When the electrode rotates between inductive converters, the envelope of the signal also changes according to a periodic law, reaching at a certain moment a maximum value proportional to the value of eccentricity.

The signal from the output of block 1 is fed to the input of amplifier 2, amplified and fed to the input of peak detector 3 and block 5 to determine the maximum signal value. The magnitude of the voltage at the output of the peak detector 3 is equal to the maximum value of the signal received from the moment of the start of the measurement to the reset. From the output of the peak detector 3, the voltage is applied to the input of the display unit 4. When the envelope reaches its maximum value from the output of block 5, a signal is received that triggers the first

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pulse generator 6, which generates a rectangular pulse fed to the input of the second driver 7 and the control input of the display unit 4. The latter is turned on and registers the amount of eccentricity. The indication time is determined by the pulse duration of the former 6. At the end of the pulse 6, the display unit 4 is turned off.

The second driver 7 runs on the falling edge of the pulse from shaper 6 and generates a short reset pulse to the control input of the peak detector 3. The signal at the output of the peak detector 3 decreases to zero (reset).

The display unit 4 records only the maximum values of the signal coming from the output of the unit 1, corresponding to the eccentricity value.

Thus, the use of a peak detector in the device, which selects the maximum signal value (corresponding to the eccentricity value), regardless of the electrode's rotational speed, as well as the maximum signal value determination unit and two drivers that control the measurement and indication according to the change in the measurement unit signal. , will improve the accuracy and performance of control electrodes.

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In addition, such an embodiment of the device eliminates the operator’s subjective errors, which also increases the accuracy of measurements.

When using a known device, the control is performed at an electrode rotation speed of 0.9-1 rev / s. A twofold increase in speed leads to a 10% increase in error by 25–30%. This does not allow an increase in productivity by increasing the rotational speed of the electrodes.

When using the proposed device, the rotation speed can be increased to 2-3 revolutions per second. At the same time, the error increases only by 1-3%.

Claims (1)

Invention Formula A device for monitoring the eccentricity of the coating. Welding electrodes, containing a series-connected measurement unit and an amplifier, an indication unit, characterized in that, in order to improve the accuracy and performance of the control, the first and second signal units pulse generators and a peak detector, while the amplifier output is connected to the input of the maximum value unit and through the peak detector to the input of the display unit, the control input of which connected to the output of the first pulse shaper. 0 five